Extrudable Oriented Polymer Composites

ABSTRACT

A novel tubular or profile shapes of co-extruded multilayer polymers. These materials contain tens to thousands of layers of milli-, micro- to nano-polymer layers. These new shapes contain contiguous layers of milli- to nano-polymer layers in three dimensions and these contiguous layers may be twisted or turned to further expand the potential microlayer geometries.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent applicationSer. No. 15/935,551 filed Mar. 26, 2018 to be patented as U.S. Pat. No.10,232,540 to be issued on Mar. 19, 2019, which is a continuation ofU.S. patent application Ser. No. 15/490,955 filed Apr. 19, 2017 nowpatented as U.S. Pat. No. 9,925,708 issued Mar. 27, 2018, which is acontinuation of U.S. patent application Ser. No. 14/185,629 filed Feb.20, 2014 now patented as U.S. Pat. No. 9,656,437 issued May 23, 2017,which claimed priority to and the benefit of U.S. ProvisionalApplication 61/767,232 filed Feb. 20, 2013, the disclosures of which areincorporated herein by reference in their entireties.

FIELD

The present disclosure generally relates to extrusion die systems. Inparticular, the present disclosure relates to the cyclical extrusion ofmaterials to generate small sized grain features, generally in the rangeof micro and nanosized grain features, in a tubular or profile shape.

BACKGROUND

Nanostructured materials are generally regarded as materials having verysmall grain feature size, typically in the range of approximately 1-100nanometers (10⁻⁹ meters). Metals, ceramics, polymeric and compositematerials may be processed in a variety of ways to form nanosizedfeatures. These materials have the potential for wide rangingapplications, including for example, industrial, biomedical, 3D printingand electronic applications. As a result, a great deal of study isongoing to gain a better understanding of the characteristics of thesematerials.

Conventional extrusion formed products are limited to approximatelytwelve layers. Micro-layer extrusion processes can extend theselimitations. Micro-layer extrusion processes that provide methods forobtaining small grain features is described in U.S. Pat. No. 7,690,908,(hereinafter the “'908 Patent”) and U.S. Patent Publication 2012/0189789(hereinafter the “'789 Publication”) both of which are commonly owned bythe assignee of the instant application, the disclosures of which areincorporated herein by reference in their entirety. Further examples ofextrusion technology are described in U.S. Pat. Nos. 6,669,458,6,533,565 and 6,945,764, also commonly owned by the assignee of theinstant application.

The typical micro-layer product is formed in a sheet. If a tubularproduct is desired, the microlayer is first formed into a sheet and thenmade into the tube. This creates a weld line or separation between themicrolayers. The '908 Patent describes a cyclical extrusion of materialsby dividing, overlapping and laminating layers of flowing material,multiplying the flow and further dividing, overlapping and laminatingthe material flow to generate small grain features and improveproperties of the formed product. Examples of the improved propertiesinclude, but are not limited to burst strength, tensile strength, tearresistance, barrier and optical properties. The '789 Publicationdescribes extruding a flow of extrusion material in a non-rotatingextrusion assembly, forming a first set of multiple laminated flowstreams from the extruded flow, amplifying a number of the laminationsby repeatedly compressing, dividing and overlapping the multiplelaminated flow streams, rejoining the parallel amplified laminatedflows, forming a first combined laminate output with nano-sized featuresfrom the rejoining; and forming a tubular shaped micro-layer productfrom the combined laminate output. Such products do not contain aso-called weld line.

BRIEF DESCRIPTION OF THE DISCLOSED EMBODIMENTS

As described herein, the exemplary embodiments overcome one or more ofthe above or other disadvantages known in the art.

The aspects of the present disclosure are directed to novel tubular orprofile shapes of co-extruded multilayer polymers. These materialscontain tens to thousands of layers of milli-, micro- to nano-polymerlayers. These new shapes contain contiguous layers of milli- tonano-polymer layers in three dimensions and these contiguous layers maybe twisted or turned to further expand the potential microlayergeometries.

Examples of Tubular Polygonal and Annular geometries are presented inFIGS. 1a-d and are depicted with a limited number of layers forillustrative purposes. Microlayer coextrusion can be used to createproducts possessing ten to thousands of layers. The layers can containthe same or different polymer and contain different fillers, particlesor chemicals. An example with two compositions of the layers couldcontain composition A and composition B and the layers could alternateA-B-A-B-A-B. or even A-B-B-A-B-B-A-B-B. Three component compositionscontaining compositions A, B and C may likewise form alternating layerssuch as A-B-C-A-B-C-A-B-C. Such microlayer extrusions can form their ownproducts or can be applied onto a core. Inner and outer layers can alsobe extruded with these layers. These products can be hollow or rod likewith varying profiles.

Other alignment embodiments include diamond, rombus, pentagon, andhexagon.

Alignment embodiments also include twisted shapes such as spirals.

Another embodiment relates to products containing a hollow inner corewith composite milli, micro, or nano layers extruded on the exterior.

Another embodiment relates to products containing a composite inner coreextruded with composite milli, micro, or nano layers on the exterior.

Another embodiment relates to I-beam products.

Another embodiment relates to products containing multiple layers ofvarying components.

Another embodiment relates to products containing filler particles orfibers. More preferred products contain filler particles or fibersaligned along the extrusion axis.

Microlayer coextrusion allows for enhanced alignment of filler particlesor fibers along the direction of the extrusion. Filler particles aremostly restrained within each layer and as they approach a magnitude ofsize similar to the fiber or particle size, shear stresses alignparticles in the direction of the extrusion. In a particle with threecharacteristic dimensions, the smallest dimension will be perpendicularto the layer boundary and the longest dimension will be in the directionof the extrusion.

Fillers also refers to flakes such as copper or tin flakes.

Fibers include single fibers or a myriad of other arrangements. Someexemplary arrangements include yarns, a tow of fibers or yarns, a weave,a non-woven, chopped fiber, a chopped fiber mat (with random or orderedformats), or combinations of these formats. The chopped fiber mat ornonwoven may be stretched, stressed, or oriented to provide somealignment of the fibers within the nonwoven or chopped fiber mat, ratherthan having a random arrangement of fibers.

Fibers also generally possess an average aspect ratio of 10-3000 andmore commonly are fibers having an average aspect ratio of 20-1000.Aspect ratios of 20-350 and 50-200 are specifically envisioned. Varioustypes of organic and inorganic fibers are suitable either inmonofilament or stranded form (including bundles of fibers bondedtogether to make a single element which serves as a single fiber in thesense of orientation and reinforcement).

Filler particles or fibers include wood fibers (including groundwood,thermomechanical pulp (TMP) and bleached or unbleached kraft or sulfitepulps), vegetable fibers (including cellulose, lignin, cotton, hemp,jute, flax, ramie, sisal and bagasse), animal fibers (includingproteinaceous strands such as silkworm silk, spider silk, sinew, catgut,wool, sea silk and hair such as cashmere wool, mohair and angora, fursuch as sheepskin, rabbit, mink, fox, or beaver), other syntheticpolymeric fibers (including rayon, modal, Lyocell polyamide nylon, PETor PBT polyester, phenol-formaldehyde (PF), polyvinyl alcohol fiber(PVA) vinylon, polyvinyl chloride fiber (PVC) vinyon, polyolefins (PPand PE) olefin fiber, acrylic polyesters, pure polyester, aromaticpolyamids (aramids) such as Twaron, Kevlar and Nomex, polyethylene (PE),HMPE (e.g. Dyneema or Spectra), polyurethane fiber, and elastomersincluding spandex), metallic fibers such as those drawn from ductilemetals such as copper, gold or silver and extruded or deposited frommore brittle ones, such as nickel, aluminum or iron, stainless steelfibers, silicon carbide fibers, clay particles, carbon fibers or glassfibers.

Particularly important fibers include the so-called micro and nanofibers including nanocellulous fibers and synthetic nanotubulesincluding carbon nanotubes, inorganic nanotubes and DNA nanotubes.

Fibers also includes microfibers known as sub-denier fibers (such aspolyester drawn to 0.5 dn). Denier and Detex fibers include fiberscategorized by weight and length measurements. Fiber designs alsoincludes fibers split into multiple finer fibers. Most synthetic fibersare round in cross-section, but special designs can be hollow, oval,star-shaped or trilobal. The latter design provides more opticallyreflective properties. Synthetic fibers may also be crimped to provide awoven, non woven or knitted structure. Fiber surfaces can also be dullor bright. Dull surfaces reflect more light while bright tends totransmit light and make the fiber more transparent.

Very short and/or irregular fibers have been called fibrils. Naturalcellulose, such as cotton or bleached kraft, show smaller fibrilsjutting out and away from the main fiber structure.

Fibers alignment can also be tailored by the application of externalforces such as magnetic fields.

These and other aspects and advantages of the exemplary embodiments willbecome apparent from the following detailed description considered inconjunction with the accompanying drawings. It is to be understood,however, that the drawings are designed solely for purposes ofillustration and not as a definition of the limits of the invention, forwhich reference should be made to the appended claims. Additionalaspects and advantages of the invention will be set forth in thedescription that follows, and in part will be obvious from thedescription, or may be learned by practice of the invention. Moreover,the aspects and advantages of the invention may be realized and obtainedby means of the instrumentalities and combinations particularly pointedout in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings illustrate presently preferred embodiments ofthe present disclosure, and together with the general description givenabove and the detailed description given below, serve to explain theprinciples of the present disclosure. As shown throughout the drawings,like reference numerals designate like or corresponding parts.

FIGS. 1a and 1b illustrate examples of tubular polygonal microlayergeometries incorporating aspects of the disclosed embodiments.

FIGS. 1c and 1d illustrate examples of tubular annular microlayergeometries in a product incorporating aspects of the disclosedembodiments.

FIG. 2 illustrates the alignment of fibers along the extruded layers ina product incorporating aspects of the disclosed embodiments.

FIG. 3 illustrates an example of larger extrusion layers, no-layers orcoated materials containing fibers have fiber orientations that are morerandom or less ordered in a product incorporating aspects of thedisclosed embodiments.

FIG. 4 illustrates a fully oriented composite beam in a productincorporating aspects of the disclosed embodiments.

FIG. 5 illustrates a hollow core in a hollow end product incorporatingaspects of the disclosed embodiments.

FIG. 6 illustrates a composite inner core extruded with composite small,micro or nano layers on the exterior in a product incorporating aspectsof the disclosed embodiments.

FIG. 7 illustrates multiple levels of layers containing differentcompositions in a product incorporating aspects of the disclosedembodiments.

FIGS. 8a and 8b illustrate exemplary I beam profile configurations in aproduct incorporating aspects of the disclosed embodiments.

FIG. 9 illustrate an exemplary alignment of particles to create atortuous path in a product incorporating aspects of the disclosedembodiments.

DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENTS OF THE DISCLOSURE

Rotating small, micro and nano-layer extrusion processes are describedin U.S. Pat. No. 7,690,908. Small, micro and nano layer Non-rotatingextrusion processes are described in U.S. Patent Publication2012/0189789. U.S. patent application Ser. No. 14/084,601 filed Nov. 19,2013, entitled “Method Of Creating Multilayered Products Through TheFolding Of Continuous Layers,” U.S. patent application Ser. No.13/972,753 filed Aug. 21, 2013, entitled “Microlayer Coextrusion ofOptical End Products, U.S. Patent Publication 2013/344,271, and U.S.Patent Publication 2014/034,355 refer to other extrusion processes andmethods. Each of the disclosures of the aforesaid patent, publicationand application are herein incorporated by reference in their entirety.Altering the die plate orientation around the central extrusion axisallows for the preparation of new geometric extrusion products describedin further detail herein. Polygonal and annular geometries are describedabove. Such geometries composed of milli, micro and nano layerextrusions can also include fillers and fibers. When these fillers orfibers are extruded in the small, milli, micro, or nano layers thefibers tend to align along extruded layers such as depicted in FIG. 2.The relative sizes of fillers to sizes of layers will affect the degreeof orientation.

Although the embodiments disclosed herein will be described withreference to the drawings, it should be understood that the embodimentsdisclosed herein can be embodied in many alternate forms. In additionalany suitable size, shape or type of elements or materials could be used.

Larger extrusion layers, no-layers or coated materials containing fibershave fiber orientations that are more random or less ordered, such asdepicted in FIG. 3.

Orientation of fibers creates anisotropic mechanical properties in theproduct. This is important in the creation of composite materials.Extrusion in general has an orienting effect on fibers, however theinclusion of microlayers will amplify the degree of orientation. If thefiber has stronger mechanical properties than the matrix polymer, theproduct will be stronger in the direction of the fibers. The layering ofmaterials has the benefit of resisting crack propagation from one layerthrough the next.

EXAMPLE PRODUCT GEOMETRIES Example 1: Fully Oriented Composite Beam

A fully oriented composite beam, FIG. 4, may be prepared by coextrusionof two or more compositions made up of solely small, milli, micro, ornano layers to ensure complete orientation of the fiber particles. Thisbeam may have enhanced strength in the direction of extrusion and bemore resistant to bending perpendicular to the fiber orientation.

Example 2: Hollow Beam

A hollow composite beam, FIG. 5, may be prepared by coextrusion of thesame base composition wherein the compositions contain differentexcipients. These beams may be made up of solely small, milli, micro, ornano layers.

Example 3: Beam Core With Oriented Outer Layers

Another product entails a composite inner core extruded with compositesmall, micro or nano layers on the exterior (see FIG. 6). In thisproduct, the layers may have axially oriented fibers or particles whilefibers in the center core would remain less oriented. This product wouldhave outer layers for enhanced anisotropic strength similar to theproduct above while the inner core would provide more strength in otherdirections. The location of the oriented fibers on the outside of theproduct is particularly important for enhanced bending resistance. Thecore in this product could also be foamed in order to reduce weight.

Example 4: Multiple Levels of Layers

Multiple levels of layers containing different compositions can beextruded (see FIG. 7). Layers can be of variable size and compositionwith different fillers or fibers and with or without a core. Suchlayering allows for isolation or insulation of conducting layers oroptical zones.

Example 5: I-Beam

The extrusion methods described herein yield various profileconfigurations, including cylindrical, I-beam (see FIGS. 8a and b ),C-channel, L-shaped, rectangular, square, hollow cylinder. Each of theseextrusions may have differential inclusion of fillers and fibers as wellas the presence or absence of core material.

Fiber Composites

Fibers such as carbon fiber, glass fiber, Kevlar, etc. have been used inconjunction with polymers to form composite materials. These compositescan be made with long continuous fibers where a polymer matrix isapplied onto the fibers or they can be made with shorter fibers that aremixed with polymer and formed into a desired shape. These compositematerials have desirable mechanical properties while maintaining a lowdensity. The ability to orient fibers allows for the mechanicalproperties to be enhanced in a desired direction where the load will begreatest which allows for less material to be used to obtain a desiredstrength. These materials are found in in a wide range of products suchas cars, jets, wind turbines and sporting goods.

Through microlayer coextrusion, discontinuous fiber composites can beformed with oriented fibers in the direction of the extrusion. Withenhanced mechanical properties in this direction, the products willprovide a strong tensile strength as well as a strong resistance tobending with load perpendicular to the oriented direction. The examplegeometries in FIGS. 1 through 3 and 4 through 8 would all be applicableto these composites. The cores in FIGS. 1b , 6, 7 and 8 b could also besome kind of lightweight structure such as honeycomb in order to reduceweight. As mentioned above the core may also contain a less orientedfiller/fiber composite to enhance strength in other directions. Hollowgeometries such as in FIG. 5 could be used as casings for internalcomponents of a product after the extrusion process. Such a case couldalso be made with multiple levels of layers such as in FIG. 7. The otherlevel of layers could have microlayered polmer containing metallicflakes or particles which would align to enhance conductivity andprovide EMI shielding.

Wood Plastic Composites

Wood plastic composites have been used as a replacement for preservativetreated and other more expensive woods. Wood filler plastic compositesare advantageous because they are durable, require low maintenance, willnot warp, splinter, or crack, and can be manufactured to be resistant toUV light. The plastic makes the composities very workable and can beproduced to meet almost any designed shape. Wood plastic composites arealso considered a sustainable material because they can be made usingrecycled plastic and the waste products from the wood industry. Thehigher density allows the wood plastic composites to better hold screws,but also makes the final product heavier. For this reason many woodplastic composites are designed with a hollow cross section.

Properties of the composite can be controlled though polymer type, woodfiber size and type, additives such as processing aids or propertyenhancers, and also wood fiber orientation. Polymers typically usedinclude low and high density polyethylene, polypropylene, and polyvinylchloride. These polymers are suitable as their melting temperature isbelow the thermal decomposition temperature of the wood fibers. Someproperty enhancers that are commonly used include biocides, inorganicfillers, fire retardants, ultraviolet stabilizers, and colorants.

Fiber orientation plays a strong role in determining the properties ofan extruded wood plastic composite. The nanolayer extrusion would createstrong fiber orientation within each individual layer. This would resultin unique and anistropic wood plastic composite properties. These woodplastic composites would have increased strength and tensile modulusalong with more desirable coefficient of thermal expansion and modulusof elasticity.

In one embodiment of an extruded layered wood plastic composite thelayers of wood/plastic mixture would comprise the entire structure of ahollow profile (FIG. 5). This structure would have very stronganisotropic properties. The orientation of the fibers would decreasecrack propagation perpendicular to the direction of extrusion. Thehollow structure also serves to lower the overall weight and increasethe insulation properties of the product.

In another embodiment (FIG. 6) the product would contain outer layers(e.g. skin) of wood plastic composite with an inner unlayered core. Thisembodiment combines the strongly anisotropic properties of the layeredwood composite with the unoriented properties of the core. This corecould also be produced through foaming. Foaming the inner layer wouldlower the density of the final product and also increase insulationproperties. This layering method may be used to add desired mechanicalproperties to the product through judicious choice of the orientation ofthese layers.

Multilayered Clay Product

Nanoscale particles of clay dispersed within a polymer matrix have beenshown to improve mechanical, fire, and barrier properties. Claynanoparticles provide an environmentally friendly alternative toadditives typically used to improve polymer properties.

The improvement in material properties is largely dependent on theorientation and degree of dispersion of the clay nano-particles.Dispersion of clay nano-composites is difficult due to the hydrophilicnature of the clay platelets in contrast to the hydrophobic nature ofthe polymer.

The use of clay nanoparticles to provide fire resistance has arisen as amore environmentally friendly alternative to the halogen-based fireretardants commonly used today. Currently fire retardation using claynanoparticles typically involves layer by layer deposition of clay andpolymer matrices. This process is time consuming and typically involvesthe use of harmful solvents. Using melt processing would provide manyadvantages over clay/polymer deposition using solvents: it is a processthat is widely used and understood in industry. Melt processing is moreenvironmentally friendly, and there is a greater flexibility in theavailable plastics that can be used because there is no requirement tobe solvent compatable. Fire retardation using clay nanocompositesstongly depends on the dispersion of the clay particles. More uniformclay dispersion allows the clay plates to entangle more easily whenexposed to heat. The entangled clay particles work to provide improvedflame resistance through the formation of char and the prevention ofdripping.

The large aspect ratio of clay particles can be used to increase barrierproperties. The alignment of particles creates a tortuous path (see FIG.9) for any permeates to travel. This path decreases the permeability ofpolymer clay nanocomposite.

The degree of dispersion of nano-sized clay particles determines themechanical, fire, and barrier properties of the polymer composite. Evendispersion of these particles is often difficult to achieve due to thematerials tendancy to form agglomerates in the polymer matrix. Variousmethods have been used to increase the dispersion of nano-particleswithin a polymer matrix including reactive extrusion where the reactionbetween the nanoparticle and polymer leads to more dispersion or the useof solvents designed to break apart the agglomerates. Extrusion of amasterbatch with predispersed nano particles can also lead to a decreaseof dispersion as the particles recombine during the extrusion process.With the microlayer extrusion process the formation of agglomerateswould be hindered due to the encapsulation of nano-material within eachlayer. Agglomerates will be less likely to form across the layerboundaries of the microlayer extrusion process. The increased dispersionwould lead to more desirable and uniform mechanical, flame, and barrierproperties.

In another embodiment of the product, the outer layers of the productwould contain layers of nano-sized clay composites on the outer surfaceof a product (FIG. 6). These layers would be used to increase fireprotection and barrier properties of the product.

Another embodiment of the product could provide added barrier and fireresistance properties to an anisotropic product (FIG. 7). The outerlayers (e.g. skin) could contain the nano-clay composite while the innerlayers and core contain a different material, such as nanocellulose orwood plastic composite. In this embodiment the clay composite and theinner layers and core could be coextruded together or the clay layerscould be added separately.

Nanocellulose Polymer Composite

Nanocellulose fibers are high aspect ratio fibers that may be used toform a composite material. This fibers can be isolated from anycellulose source, typically wood pulp. Nanocellulose fibers couldprovide an organic polymer composite that has tensile strength andstiffness properties that exceed those of typical polymerreinforcements, such as glass fibers. Along with improved mechanicalproperties, the nanocellulose composites also demonstrate decreasedpermeability to gases and water, improved thermal stability, and agreater heat distortion temperature.

Nanocellulose can be processed through a solvent or melt approach with apolymer matrix to produce a nanocomposite. The solvent approach allowsthe dispersion of the nanocellulose to be tightly controlled, but onlycertain polymers can be used in the approach. A melt processingtechnique is a green process that is industrially and economicallyviable. The hydrophilicity of the nanocellulose makes an even dispersiondifficult to obtain using melt processing. Techniques such as surfacegrafting of polymer compatable materials onto the nanocellulose hasshown some promise of improving disepersion, but the high shear ratesfound in typical extrusion processes often decrease the chances of thegrafted particle remaining attached to the nanocellulose.

Depending on the technique used to isolate the nanocellulose fibers, thetemperature stability of the fibers can become an issue during meltprocessing. One method that may be used to increase both the temperaturestability and the dispersion of the nanocellulose is to prepare thenancellulose with high molecular weight polyethylene oxide (PEO). Thismixture can then be combined and extruded with typical melt processablepolymers.

In another embodiment the exemplary product would contain layers ofnanocellulose composite throughout the entirety of the product. Thenanocellulose could be compounded with suitable polymers and/or graftedto a compatible polymer. This layering technology allows for theconfinement of nanocellulose which increase beneficial nanocellulose tonanocellulose interaction.

In another embodiment the nanocellulose layers could be extruded over asolid core (FIG. 6) through coextrusion or extrusion coating. Thisproduct would be particularly suited for enhanced barrier propertiesprovided by the outer nanocellulose layers, but would still maintain themechanical properties of the inner core.

Nanocellulose is a ‘green’ or environmentally friendly alternative tomany other fibers or fillers and has the potential to become widelyavailable. PLA (Polylactic acid) is a biodegradable polymer with whichthere has been some success in creating relatively dispersednanocellulose composites. PLA is also widely used as a filament for 3Dprinting. A microlayered nanocellulose/PLA composite filament in whichsome or all layers contain nanocellulose fibers could drasticallyimprove properties while remaining a green alternative to otherplastics.

Thus, while there have been shown, described and pointed out,fundamental novel features of the invention as applied to the exemplaryembodiments thereof, it will be understood that various omissions andsubstitutions and changes in the form and details of devices and methodsillustrated, and in their operation, may be made by those skilled in theart without departing from the spirit of the invention. Moreover, it isexpressly intended that all combinations of those elements and/or methodsteps, which perform substantially the same function in substantiallythe same way to achieve the same results, are within the scope of theinvention. Moreover, it should be recognized that structures and/orelements and/or method steps shown and/or described in connection withany disclosed form or embodiment of the invention may be incorporated inany other disclosed or described or suggested form or embodiment as ageneral matter of design choice. It is the intention, therefore, to belimited only as indicated by the scope of the claims appended hereto.

What is claimed is:
 1. A multilayered extrusion product comprising atubular microlayered composite, wherein said tubular microlayeredcomposite comprises contiguous layers without weld lines and has a shapeselected from profile, polygonal, annular, diamond, rhombus, pentagon,and hexagon wherein one or more layers of said tubular microlayeredcomposite contains organic fibers.
 2. The multilayered extrusion productaccording to claim 1, wherein said tubular microlayered compositecomprises two composition layers of composition A and composition B thatalternate in a pattern A-B-A-B-A-B or A-B-B-A-B-B-A-BB.
 3. Themultilayered extrusion product according to claim 1, comprising two ormore compositions wherein said tubular microlayered composite is hollow.4. The multilayered extrusion product according to claim 1, comprisingtwo or more compositions wherein said tubular microlayered compositecomprises a solid core.
 5. The multilayered extrusion product accordingto claim 1, comprising two or more compositions wherein said tubularmicrolayered composite comprises a skin layer.
 6. The multilayeredextrusion product according to claim 1, wherein one or more layers ofsaid tubular microlayered composite contains PLA.
 7. The multilayeredextrusion product according to claim 1, wherein said organic fiber isnanocellulose.
 8. The multilayered extrusion product according to claim1, wherein said tubular microlayered composite is a filament.
 9. Themultilayered extrusion product according to claim 8, wherein saidtubular microlayered composite filament contains PLA.